CN112243192B

CN112243192B - Communication path determining method, measuring device and measuring controller for millimeter wave signals

Info

Publication number: CN112243192B
Application number: CN201910962647.5A
Authority: CN
Inventors: 翁国执
Original assignee: Shenzhen Futaihong Precision Industry Co Ltd; Chiun Mai Communication Systems Inc
Current assignee: Shenzhen Futaihong Precision Industry Co Ltd; Chiun Mai Communication Systems Inc
Priority date: 2019-07-01
Filing date: 2019-10-11
Publication date: 2023-05-26
Anticipated expiration: 2039-10-11
Also published as: US20210006324A1; TW202105936A; CN112243192A; US11342985B2; TWI807115B

Abstract

The invention relates to a communication path determining method, a measuring device and a measuring controller for millimeter wave signals. In the invention, a first measuring device searches the list, and transmits millimeter wave signals to a second measuring device through an array antenna of the first measuring device at a first transmitting angle corresponding to transmission environment as a line of sight, and the second measuring device searches the list and receives millimeter wave signals transmitted by the first measuring device through the array antenna of the second measuring device at a first incident angle corresponding to the transmission environment as the line of sight. Thus, the communication path between the first measuring device and the second measuring device can be quickly established, so that the purpose of quick communication between the first measuring device and the second measuring device is realized.

Description

Communication path determining method, measuring device and measuring controller for millimeter wave signals

Technical Field

The present invention relates to the field of communications, and in particular, to a method for determining a communication path of a millimeter wave signal, a measurement device, and a measurement controller.

Background

Currently, in a millimeter wave communication system, if a receiving and transmitting party can know the incoming wave direction of the receiving and transmitting party, such as AOA (angle of arrival) or AOD (angle of departure, transmission angle), according to its own location information and a database of the corresponding relation between the defined incident angle and the transmission angle provided by the base station at the beginning of communication, the communication link between the receiving and transmitting party can be established rapidly. However, there is no measurement method for measuring the incident angle and the corresponding relationship between the emission angle and the position of the millimeter wave signal within the coverage of the base station.

Disclosure of Invention

In view of the above, it is necessary to provide a communication path determination method of millimeter wave signals, a measurement device, and a measurement controller to achieve rapid establishment of a communication path between measurement devices.

The utility model provides a measuring device, measuring device and measurement controller and second measuring device communication connection, measuring device includes omnidirectional antenna, array antenna, first antenna and treater, the treater respectively with omnidirectional antenna array antenna first antenna is connected, the treater is used for:

transmitting a first test request signal containing a position of the measurement device to the measurement controller through the first antenna;

receiving a first test instruction sent by the measurement controller through the first antenna, and controlling an omnidirectional antenna of the measurement device to send millimeter wave signals to the second measurement device according to the first test instruction;

receiving a third test instruction sent by the measurement controller through a first antenna of the measurement device, and controlling the measurement device to send millimeter wave signals to the second measurement device through an array antenna at different transmission angles according to the third test instruction;

Receiving a first time period and a first signal intensity sent by the measurement controller, determining a first sending angle corresponding to the first time period according to the first time period and the first signal intensity, and sending the first sending angle to the measurement controller, wherein the first signal intensity is a time from when the second measurement device receives a signal with the signal intensity exceeding a signal intensity threshold value sent by the measurement device at least at a fixed first incidence angle, and the first time period is a time from when the measurement device sends millimeter wave signals at different sending angles to when the second measurement device receives the first signal intensity;

controlling an array antenna of the measuring device to send millimeter wave signals to the second measuring device at the first sending angle according to a fifth test instruction sent by the measuring controller, and timing;

stopping timing when the first measuring device receives the feedback signal of the second measuring device to obtain a first timing time, and sending the first timing time to the measuring controller; a kind of electronic device with high-pressure air-conditioning system

Searching a list, transmitting millimeter wave signals to a second measuring device through an array antenna of the first measuring device at a first transmitting angle corresponding to the transmission environment as a line of sight, wherein the list stores the position of the measuring device, the position of the second measuring device, a first incident angle of the second measuring device, the first transmitting angle of the first measuring device and the transmission environment between the first measuring device and the second measuring device to establish a corresponding relation.

A measurement controller, respectively with first measuring device and second measuring device communication connection, measurement controller includes second antenna and processing unit, the second antenna with processing unit is connected, processing unit is used for:

receiving a first test request signal sent by the first measuring device through the second antenna, generating a first test instruction and a second test instruction according to the received first test request signal, sending the first test instruction to the first measuring device, and sending the second test instruction to the second measuring device;

receiving and storing a first incident angle sent by the second measuring device and position information of the second measuring device, generating a third test instruction and a fourth test instruction, and sending the third test instruction to the first measuring device and the fourth test instruction to the second measuring device;

receiving a first time period and a first signal intensity sent by the second measuring device, and sending the first time period and the first signal intensity to the first measuring device;

receiving and storing a first emission angle sent by the first measuring device, generating a fifth test instruction and a sixth test instruction, and sending the fifth test instruction to the first measuring device and the sixth test instruction to the second measuring device;

Receiving a first timing time sent by the first measuring device, and calculating a first path time according to a formula tt=t-Tap-Tbp from the first timing time, wherein T is the first timing time, tbp is the time for the second measuring device to process the millimeter wave signal received from the first measuring device, tap is the processing time for the first measuring device to receive the feedback signal of the second measuring device, and Tt is the first path time;

calculating a first distance from the first path time according to a formula d=c×tt/2, wherein C is a speed of light and D is the first distance;

calculating a second distance between the first measuring device and the second measuring device according to the position information of the first measuring device and the position information of the second measuring device;

calculating a difference between the second distance and the first distance, determining that the transmission environment between the first measurement device and the second measurement device is line-of-sight transmission when the difference is within a preset distance range, and determining that the transmission environment between the first measurement device and the second measurement device is non-line-of-sight transmission when the difference exceeds the preset distance range; a kind of electronic device with high-pressure air-conditioning system

And establishing a corresponding relation among the position of the first measuring device, the position of the second measuring device, the first incident angle of the second measuring device, the first emitting angle of the first measuring device and the transmission environment between the first measuring device and the second measuring device and storing the corresponding relation in a list.

A method for determining a communication path of a millimeter wave signal, the method being applied to a first measuring device, a second measuring device and a measuring controller, the measuring controller being communicatively connected to the first measuring device and the second measuring device, respectively, the method comprising:

the measurement controller generates a first test instruction and a second test instruction according to a received first test request signal which is sent by the first measurement device and contains the position of the first measurement device, sends the first test instruction to the first measurement device, and sends the second test instruction to the second measurement device;

the first measuring device controls an omnidirectional antenna of the first measuring device to send millimeter wave signals to the first measuring device according to the first test instruction;

the second measuring device controls an array antenna of the second measuring device to receive millimeter wave signals sent by the first measuring device through an omni-directional antenna of the first measuring device according to the second test instruction, determines a first incidence angle of a beam of at least one millimeter wave signal according to the signal intensity of the received millimeter wave signals, and sends position information of the second measuring device and at least one first incidence angle to the measuring controller;

The measurement controller receives and stores the first incident angle sent by the second measurement device and the position information of the second measurement device, generates a third test instruction and a fourth test instruction, and sends the third test instruction to the first measurement device and the fourth test instruction to the second measurement device;

the first measuring device controls the first measuring device to respectively send millimeter wave signals at different transmission angles through an array antenna of the first measuring device according to the third test instruction;

the second measuring device controls the first measuring device to receive millimeter wave signals sent by the first measuring device through the array antenna of the first measuring device through the array antenna according to the fourth test instruction at each first incident angle respectively;

the second measuring device judges whether the signal intensity of the received millimeter wave signal exceeds a signal intensity threshold value, if so, records the current first time period and the first signal intensity, and sends the first time period and the first signal intensity to the measuring controller;

The measurement controller receives a first time period and a first signal intensity sent by the second measurement device and sends the first time period and the first signal intensity to the first measurement device;

the first measuring device receives a first time period and first signal intensity sent by the measuring controller, determines a first emission angle corresponding to the first time period according to the first time period and the first signal intensity, and sends the first emission angle to the measuring controller;

the measurement controller receives and stores a first emission angle sent by the first measurement device, generates a fifth test instruction and a sixth test instruction, and sends the fifth test instruction to the first measurement device and the sixth test instruction to the second measurement device;

the first measuring device controls an array antenna of the first measuring device to send millimeter wave signals to the second measuring device at the first sending angle according to the fifth test instruction, and the first measuring device is timed;

the second measuring device controls an array antenna of the second measuring device to receive the millimeter wave signal sent by the first measuring device at a first incident angle according to the sixth test instruction, and sends a feedback signal to the first measuring device through the array antenna after receiving the millimeter wave signal sent by the first measuring device;

Stopping timing when the first measuring device receives the feedback signal to obtain a first timing time, and sending the first timing time to the measuring controller;

the measurement controller calculates a first path time according to a formula tt=t-Tap-Tbp, wherein T is the first timing time, tbp is the time of the second measurement device for processing the millimeter wave signal received from the first measurement device, tap is the processing time of the first measurement device for receiving the feedback signal of the second measurement device, and Tt is the first path time;

the measurement controller calculates a first distance from the first path time according to a formula d=c×tt/2, wherein C is a speed of light, D is the first distance, and calculates a second distance between the first measurement device and the second measurement device according to the position information of the first measurement device and the position information of the second measurement device;

the measurement controller calculates a difference between the second distance and the first distance, determines that a transmission environment between the first measurement device and the second measurement device is line-of-sight transmission when the difference is within a preset distance range, and determines that the transmission environment between the first measurement device and the second measurement device is non-line-of-sight transmission when the difference exceeds the preset distance range;

The measurement controller establishes a corresponding relation among the position of the first measurement device, the position of the second measurement device, the first incident angle of the second measurement device, the first emission angle of the first measurement device and the transmission environment between the first measurement device and the second measurement device and stores the corresponding relation in a list;

the first measuring device searches the list and transmits millimeter wave signals to the second measuring device through an array antenna of the first measuring device at a first transmitting angle corresponding to the transmission environment as the line of sight transmission; a kind of electronic device with high-pressure air-conditioning system

The second measuring device searches the list and receives millimeter wave signals sent by the first measuring device through an array antenna of the second measuring device at a first incident angle corresponding to transmission environment as line of sight transmission.

In the invention, a first measuring device searches the list, and transmits millimeter wave signals to a second measuring device through an array antenna of the first measuring device at a first transmitting angle corresponding to transmission environment as a line of sight, and the second measuring device searches the list and receives millimeter wave signals transmitted by the first measuring device through the array antenna of the second measuring device at a first incident angle corresponding to the transmission environment as the line of sight. Thus, the communication path between the first measuring device and the second measuring device can be quickly established, so that the purpose of quick communication between the first measuring device and the second measuring device is realized.

Drawings

Fig. 1 is an application environment diagram of a communication path determining method of millimeter wave signals in an embodiment of the present invention.

Fig. 2 is a functional block diagram of a measuring device according to an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of a measuring device according to an embodiment of the invention.

FIG. 4 is a functional block diagram of a measurement controller according to an embodiment of the invention

Fig. 5 is a functional block diagram of a communication path determination system of millimeter wave signals in one embodiment of the invention.

FIG. 6 is a schematic diagram of a second measurement device receiving a signal transmitted by a first measurement device according to an embodiment of the invention.

FIG. 7 is a schematic diagram of a measurement method of Tap and Tbp in an embodiment of the invention.

Fig. 8 is a flowchart of a method for determining a communication path of a millimeter wave signal according to an embodiment of the present invention.

Description of the main reference signs

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The invention will be further described in the following detailed description in conjunction with the above-described figures.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It will be understood that when an element is referred to as being "electrically connected" to another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "electrically connected" to another element, it can be in contact, e.g., by way of a wire connection, or can be in contactless connection, e.g., by way of contactless coupling.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Some embodiments of the present invention are described in detail below with reference to the accompanying drawings. The following embodiments and features of the embodiments may be combined with each other without conflict.

Referring to fig. 1, an application environment diagram of a method for determining a communication path of a millimeter wave signal according to an embodiment of the invention is shown. The method is used in at least two measuring devices 1 and a measuring controller 2. The two measuring devices 1 are each connected in communication with a measuring controller 2 by means of wireless signals. The two measuring devices 1 are connected to each other by means of millimeter wave signals. In the present embodiment, the two measuring devices 1 have the same configuration, and for convenience of description, the two measuring devices are defined as a first measuring device 11 and a second measuring device 12, respectively. In this embodiment, the first measurement device 11 may be a millimeter wave base station, the second measurement device 12 may be a mobile device such as a mobile phone, and the measurement controller 2 may be a macro base station.

Referring to fig. 2, a functional block diagram of a measuring device 1 according to an embodiment of the invention is shown. The measuring device 1 comprises an omnidirectional antenna 111, an array antenna 112, a first antenna 113, a positioning unit 114, a magnetic azimuth meter 115, a processor 116 and a memory 117. The omni-directional antenna 111 may be an array omni-directional antenna or a microstrip omni-directional antenna. In this embodiment, the array antenna 112 is a 3×1 antenna array, for example, a 16-channel 3×1 antenna array. For transmitting and receiving information over a set of channels (e.g., 16 channels) and for generating antenna beams according to a set of digital or hybrid beamforming processes. The first antenna 113 is used for communication connection with the measurement controller 2, for example, the measurement device 1 transmits signals to the measurement controller 2 or receives signals transmitted to the measurement device by the measurement controller 2 via the first antenna 113. In this embodiment, the first antenna 113 receives a low frequency wireless signal in the 6GHz range.

The positioning unit 114 is used for acquiring position information of the measuring device 1. In this embodiment, the positioning unit 114 may be a GPS device. In one embodiment, the positioning unit 114 is a Differential GPS device. In another embodiment, the positioning unit 114 is a Real-Time Kinematic (RTK) system. The magnetic azimuth meter (Magnetometer) 115 is used to measure the azimuth angle of the measuring device 1. In the present embodiment, the magnetic azimuth meter 115 measures the north-positive direction of the measuring device 1, and uses the north-positive direction as the azimuth angle of the measuring device 1. It should be understood that the azimuth angle of the measuring device 1 measured by the magnetic azimuth meter 115 is not limited to the north direction, but may be the south direction, the east direction or the west direction, and the present invention is not limited thereto.

The processor 116 is configured to control the measuring device 1 to receive millimeter wave signals through the omni-directional antenna 111 or the array antenna 112, and to receive wireless signals transmitted by the measurement controller 2 through the first antenna 113. In this embodiment, the processor 116 may be a central processing module (Central Processing Unit, CPU), but may also be other general purpose processors, digital signal processors (Digital Signal Processor, DSP), application specific integrated circuits (Application Specific Integrated Circuit, ASIC), off-the-shelf programmable gate arrays (Field-Programmable Gate Array, FPGA) or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, or the like. The processor 116 may be a microprocessor or any conventional processor or the like, and the processor 116 may also be a control center of the measuring device 1, with various interfaces and lines connecting the various parts of the whole measuring device 1. In this embodiment, the memory 117 is used to store data and/or software codes. The memory 117 may be an internal storage unit in the measuring device 1, such as a hard disk or a memory in the measuring device 1. In another embodiment, the memory 117 may be an external storage device in the measuring apparatus 1, for example, a plug-in hard disk, a Smart Media Card (SMC), a Secure Digital (SD) Card, a Flash memory Card (Flash Card) or the like, which are provided on the measuring apparatus 1.

Referring to fig. 3, a schematic structure of a measuring device 1 according to an embodiment of the invention is shown. The measuring device 1 further comprises a transmitter 20, a receiver 30, a first switching module 40, a band-pass filter 50, a second switching module 60, a beamformer 70 and an oscillator 80 with a phase locked loop. The first switch module 40 includes two first input terminals 401 and a first output terminal 402. Two first input terminals 401 of the first switch module 40 may be connected to and communicate with the first output terminal 402, respectively. The second switch module 60 includes a second input 601 and two second outputs 602. The second input terminals 601 of the second switch module 60 may be connected to and communicate with two second output terminals 602, respectively. The transmitter 20 and the receiver 30 are connected to two first inputs 401 of the first switch module 40, respectively. The first output 402 of the first switching module 40 is connected via the band-pass filter 50 to the second input 601 of the second switching module 60. The two second outputs 602 of the second switch module 60 are connected to the omnidirectional antenna 111 and the beamformer 70, respectively. The array antenna 112 is disposed on the beamformer 70.

In this embodiment, the transmitter 20 includes a baseband signal generator 201, a first intermediate frequency converter 202, a first band pass filter 203, and an up-converter 204. The baseband signal generator 201 is connected to the first intermediate frequency converter 202, the first intermediate frequency converter 202 is connected to the first band pass filter 203, the first band pass filter 203 is connected to the up converter 204, and the up converter 204 is connected to a first input 401 of the first switching module 40. The first output 402 of the first switch module 40 is connected to the band pass filter 50. In this embodiment, the baseband signal generator 201 is configured to generate a baseband signal. The first intermediate frequency converter 202 is configured to convert the generated baseband signal to an intermediate frequency signal. In this embodiment, the bandwidth of the intermediate frequency signal may be 2.4GHz. The first band-pass filter 203 is configured to filter the intermediate frequency signal. In this embodiment, the bandwidth of the first band-pass filter 203 is 2.4-2.4835GHz. The up-converter 204 is used to up-convert the intermediate frequency signal to a target frequency signal. The target frequency signal may be a millimeter wave signal. The target frequency signal is transmitted through the first switch module 40 and the second switch module 60 and then sent out through the omni-directional antenna 111 or the array antenna 112. The oscillator 80 is connected to the baseband signal generator 201, the first intermediate frequency converter 202 and the up-converter 204, respectively, for providing local carriers for the baseband signal generator 201, the first intermediate frequency converter 202 and the up-converter 204.

In this embodiment, the receiver 30 includes a baseband signal receiver 301, a second intermediate frequency converter 302, a second bandpass filter 303, and a downconverter 304. The baseband signal receiver 301 is connected to the second intermediate frequency converter 302, the second intermediate frequency converter 302 is connected to the second band-pass filter 303, the second band-pass filter 303 is connected to the down converter 304, and the down converter 304 is connected to the first input 601 of the second switch module 60. In this embodiment, the omni-directional antenna 111 or the array antenna 112 transmits the received millimeter wave signal to the down converter 304 through the second switch module 60 and the first switch module 40, respectively. The down converter 304 down-converts the received millimeter wave signal to an intermediate frequency signal. The intermediate frequency signal is filtered by the second band-pass filter 303 and then frequency-converted by the second intermediate frequency converter 302 to obtain a baseband signal. The baseband signal is received by the baseband signal receiver 301. In this embodiment, the bandwidth of the second band-pass filter 303 is 2.4-2.4835GHz. In this embodiment, the baseband signal is a chirp signal (chirp signal). In this embodiment, the bandwidth of the baseband signal may be 400KHz, 1.6MHz, 20MHz, 80MHz, or 500MHz. In this embodiment, the oscillator 80 is connected to the baseband signal receiver 301, the second intermediate frequency converter 302, and the down converter 304, respectively, and is configured to provide local carriers for the baseband signal receiver 301, the second intermediate frequency converter 302, and the down converter 304. In this embodiment, the processor 116 is connected to the baseband signal generator 201, the baseband signal receiver 301, the oscillator 80, the first intermediate frequency converter 202, the second intermediate frequency converter 302, the up-converter 204, the down-converter 304, the first switch module 40, the second switch module 60, the omnidirectional antenna 111, and the beamformer 70, respectively.

Referring to fig. 4, a functional block diagram of the measurement controller 2 according to an embodiment of the invention is shown. In this embodiment, the measurement controller 2 includes a second antenna 21, a processing unit 22, and a storage unit 23. The second antenna 21 is used for receiving and transmitting wireless signals, for example, the measurement controller 2 transmits test instructions to the measurement device 1 via the second antenna 21. In this embodiment, the processing unit 22 may be a central processing module, but may also be other general purpose processors, digital signal processors, application specific integrated circuits, off-the-shelf programmable gate arrays or other programmable logic devices, discrete gate or transistor logic devices, discrete hardware components, etc. The processing unit 22 may be a microprocessor or any conventional processor or the like, and the processing unit 22 may also be a control center of the measurement controller 2, with various interfaces and lines connecting the various parts of the entire measurement controller 2. In this embodiment, the storage unit 23 is configured to store data and/or software codes. The storage unit 23 may be an internal storage unit in the measurement controller 2, such as a hard disk or a memory in the measurement controller 2. In another embodiment, the storage unit 23 may also be an external storage device in the measurement controller 2, such as a plug-in hard disk, a smart memory card, a secure digital card, a flash memory card, etc. provided on the measurement controller 2.

Referring to fig. 5, a functional block diagram of a millimeter wave signal communication path determining system 100 according to an embodiment of the invention is shown, in which the millimeter wave signal communication path determining system 100 includes one or more modules, and the one or more modules operate in the measuring device 1 and the measuring controller 2. In this embodiment, the millimeter wave signal communication path determining system 100 includes a first test request module 101, a first test response module 102, a first test module 103, a second test module 104, a second test response module 105, a third test response module 106, a second test request module 107, a fourth test response module 108, a third test module 109, a fourth test module 120, a fifth test response module 121, a sixth test response module 122, and an update module 123. The first test request module 101, the first test module 103, the fourth test module 120, and the update module 123 are stored in the memory 117 of the first measurement device 11, and are invoked and executed by the processor 116. The second test module 104, the second test request module 107 and the third test module 109 are stored in the memory 117 of the second measurement device 12 and are invoked by the processor 116 for execution. The first test response module 102, the second test response module 105, the third test response module 106, the fourth test response module 108, the fifth test response module 121, and the sixth test response module 122 are stored in the storage unit 23 of the measurement controller 2, and are invoked and executed by the processing unit 22. The modules referred to in the present invention refer to a series of computer program instruction segments capable of performing specific functions, which are more suitable than programs for describing the execution of software in the communication path determination system 100 of millimeter wave signals.

The first test request module 101 is applied to the first measurement device 11, and is configured to send a first test request signal to the measurement controller 2, where the first test request signal includes location information of the first measurement device 11.

In this embodiment, the first test request module 101 sends the first test request signal containing the position information of the first measurement device 11 to the measurement controller 2 through the first antenna 113 in the first measurement device 11.

The first test response module 102 is applied in the measurement controller 2, and is configured to generate a first test instruction and a second test instruction according to the received first test request signal, send the first test instruction to the first measurement device 11, and send the second test instruction to the second measurement device 12.

In this embodiment, the first test response module 102 receives the first test request signal sent by the first measurement device 11 through the second antenna 21, generates a first test instruction and a second test instruction according to the received first test request signal, sends the first test instruction to the first measurement device 11 through the second antenna 21, sends the second test instruction to the second measurement device 12 through the second antenna 21, and stores the position information of the first measurement device 11 in the first test request signal.

The first test module 103 is applied to the first measurement device 11, and is configured to receive a first test instruction sent by the measurement controller 2 and control the omni-directional antenna 111 of the first measurement device 11 to send a millimeter wave signal to the second measurement device 12 according to the first test instruction.

In this embodiment, the first measuring device 11 receives the first test command sent by the measurement controller 2 through the first antenna 113, and then controls the omnidirectional antenna 111 to send the millimeter wave signal to the second measuring device 12.

The second test module 104 is applied to the second measurement device 12, and is configured to receive a second test instruction sent by the measurement controller 2 and control the array antenna 112 Of the second measurement device 12 according to the second test instruction to receive a millimeter wave signal sent by the first measurement device 11 through the omni-directional antenna 111 Of the second measurement device 12, determine a first Angle Of incidence (AOA) Of a beam Of at least one millimeter wave signal according to a signal strength Of the received millimeter wave signal, and send the position information Of the second measurement device 12 and at least one first Angle Of incidence to the measurement controller 2.

In this embodiment, the array antenna 112 has four sectors, each having at least one sector antenna. The second test module 104 controls the sector antennas in the four sectors of the array antenna 112 to scan according to the second test instruction sent by the measurement controller 2 and receives the millimeter wave signals sent by the first measurement device 11 at different incident angles. The second test module 104 determines an incident angle corresponding to the received millimeter wave signal when the signal strength exceeds a signal strength threshold as a first incident angle and sends the first incident angle and the position of the second measurement device 12 to the measurement controller 2. In this embodiment, when the second test module 104 controls the sector antennas in the four sectors of the second measurement device 12 to scan within a preset cycle scan time and receive the millimeter wave signals sent by the first measurement device 11 at different incident angles, the four sectors receive the millimeter wave signals sent by the first measurement device 11 at different incident angles of beams through the sector antennas in 0 to 90 degrees, 90 to 180 degrees, 180 to 270 degrees, and 270 to 360 degrees, respectively. In this embodiment, the sector antenna is a 1×16 antenna structure or a 1×8 antenna structure.

In another embodiment, the array antenna 112 has three sectors, each sector having at least one sector antenna. The second test module 104 controls sector antennas in the three sectors of the second measurement device 12 to scan according to the second test instruction sent by the measurement controller 2 and receives millimeter wave signals sent by the first measurement device 11 at different incident angles. In this embodiment, when the second test module 104 controls the sector antennas in the three sectors of the second measurement device 12 to scan within a preset cycle scan time and receive the millimeter wave signals sent by the first measurement device 11 at different incident angles, the three sectors receive the millimeter wave signals sent by the first measurement device 11 at different incident angles of beams through the sector antennas in 0 to 120 degrees, 120 to 240 degrees, and 240 to 360 degrees, respectively.

The second test response module 105 is applied in the measurement controller 2, and is configured to receive and store the first incident angle sent by the second measurement device 12 and the position information of the second measurement device 12, generate a third test instruction and a fourth test instruction, and send the third test instruction to the first measurement device 11 and the fourth test instruction to the second measurement device 12.

The first test module 103 receives a third test instruction sent by the measurement controller 2 through the first antenna 113 of the first measurement device 11 and controls the first measurement device 11 to send millimeter wave signals at different emission angles (Angle Of Departure, AOD) through the array antenna 112 according to the third test instruction. In this embodiment, the first test module 103 controls the sector antennas in the four sectors of the first measurement device 11 to scan within the preset cyclic scan time according to the third test instruction sent by the measurement controller 2, and sends millimeter wave signals at different transmission angles. In this embodiment, when the first test module 103 controls the sector antennas in the four sectors of the first measurement device 112 to scan and transmit millimeter wave signals at different transmission angles, the four sectors transmit millimeter wave signals to the second measurement device 12 at different transmission angles through the array antenna 112 in 0 to 90 degrees, 90 to 180 degrees, 180 to 270 degrees, and 270 to 360 degrees, respectively.

The second test module 104 receives a fourth test instruction sent by the measurement controller 2 through the first antenna 113 of the second measurement device 12, and controls the second measurement device 12 to receive the millimeter wave signal sent by the first measurement device 11 through the array antenna 112 of the first measurement device 11 through the array antenna 112 at each first incident angle according to the fourth test instruction.

Referring to fig. 6, a schematic diagram of the second measuring device 12 receiving a signal transmitted by the first measuring device 11 according to an embodiment of the invention is shown. In this embodiment, the second test module 104 determines whether the signal strength of the received millimeter wave signal exceeds a signal strength threshold, if the signal strength of the received millimeter wave signal exceeds the signal strength threshold, records a current first time period and a first signal strength, and sends the first time period and the first signal strength to the measurement controller 2. In this embodiment, the first signal strength is a signal strength corresponding to a millimeter wave signal whose signal strength exceeds a signal strength threshold when the second measuring device 12 receives the millimeter wave signal sent by the first measuring device 11 at least a fixed first incident angle; the first period is a time from when the array antenna 112 of the second measurement device 12 scans and receives the millimeter wave signal transmitted by the first measurement device 11 to when the signal strength of the received millimeter wave signal is the first signal strength.

The third test response module 106 is applied in the measurement controller 2, and is configured to receive the first time period and the first signal strength sent by the second measurement device 12, and send the first time period and the first signal strength to the first measurement device 11. In this embodiment, the third test response module 106 receives the first time period and the first signal strength transmitted by the second measurement device 12 through the second antenna 21, and transmits the first time period and the first signal strength to the first measurement device 11.

The first test module 103 determines a first emission angle corresponding to a first time period according to the first time period and the first signal strength sent by the measurement controller 2, and sends the first emission angle to the measurement controller 2. Specifically, the first test module 103 determines the first emission angle corresponding to the first period of time during a preset cyclic scan time of the scanning performed by the array antenna 112 of the first measurement device 11. The first test module 103 sends the first emission angle to the measurement controller 2 via the first antenna 113.

The third test response module 106 receives and stores the first emission angle sent by the first measurement device 11, generates a fifth test instruction and a sixth test instruction, and sends the fifth test instruction to the first measurement device 11 and the sixth test instruction to the second measurement device 12.

The first test module 103 controls the array antenna 112 of the first measurement device 11 to transmit the millimeter wave signal to the second measurement device 12 at the first transmission angle according to the fifth test instruction, and performs timing when the first measurement device transmits the millimeter wave signal to the second measurement device 12 at the first transmission angle.

The second test module 104 controls the array antenna 112 of the second measurement device 12 to receive the millimeter wave signal sent by the first measurement device 11 at the first incident angle according to the sixth test instruction, and sends a feedback signal to the first measurement device 11 through the array antenna 112 after receiving the millimeter wave signal sent by the first measurement device 11. The first test module 103 stops timing to obtain a first timing time when receiving the feedback signal, and sends the first timing time to the measurement controller 2. The third test response module 106 calculates the first path time according to the formula tt=t-Tap-Tbp, where T is the first timing time, tbp is the time for the second measurement device 12 to process the millimeter wave signal received from the first measurement device 11, tap is the processing time for the first measurement device 11 to receive the feedback signal from the second measurement device 12, and Tt is the first path time. In this embodiment, since the time value of the Tap and the Tbp will not change in different transmission environments, the total time of the Tap and the Tbp can be measured in a known transmission environment.

Referring to FIG. 7, a schematic diagram of the measurement method of Tap and Tbp is shown. In this embodiment, the measurement method of Tap and Tbp includes the steps of: placing the first measuring device 11 at a predetermined distance from the second measuring device 12, in this embodiment 20 meters; controlling the array antenna 112 of the first measuring device 11 to transmit millimeter wave signals to the second measuring device 12, and timing; controlling the array antenna 112 of the second measuring device 12 to receive the millimeter wave signal sent by the first measuring device 11, and sending a feedback signal to the first measuring device 11 through the array antenna 112 after receiving the millimeter wave signal sent by the first measuring device 11; controlling the first measuring device 11 to stop timing when receiving the feedback signal to obtain a timing time, wherein the timing time is T15, T12 is a time from when the second measuring device 12 starts to send the millimeter wave signal to the first measuring device 11 to when the second measuring device 12 receives the millimeter wave signal sent by the first measuring device 11, tbp is a time from when the second measuring device 12 processes the millimeter wave signal received by the first measuring device 11, T34 is a time from when the second measuring device 12 starts to send the feedback signal to when the first measuring device 11 receives the feedback signal, and Tap is a processing time from when the first measuring device 11 receives the feedback signal of the second measuring device 12; calculating T12 and T34 according to the formula t12=t34=d/C, wherein d is a preset distance between the first measuring device 11 and the second measuring device 12, and C is a light speed; the total time of Tap and Tbp is calculated according to the formula T' =tap+tbp=t15-T12-T34.

In this embodiment, the third test response module 106 calculates the first distance from the first path time according to the formula d=c×tt/2, where C is the speed of light and D is the first distance. The third test response module 106 is further configured to calculate a second distance between the first measurement device 11 and the second measurement device 12 according to the position information of the first measurement device 11 and the position information of the second measurement device 12. The third test response module 106 calculates a difference between the second distance and the first distance, and determines whether the calculated difference is greater than a preset distance range. When the difference is within the preset distance range, the third test response module 106 determines that the transmission environment between the first measurement device 11 and the second measurement device 12 is Line Of Sight (LOS) transmission. When the difference exceeds the preset distance range, the third test response module 106 determines that the transmission environment between the first measurement device 11 and the second measurement device 12 is a non-line of sight transmission (NLOS, not Line Of Signal). In this embodiment, the third test response module 106 associates the position of the first measurement device 11, the position of the second measurement device 12, the first incident angle of the second measurement device 12, the first emission angle of the first measurement device 11, and the transmission environment between the first measurement device 11 and the second measurement device 12 with each other and stores the same in a list.

The first test module 103 searches the list and controls the first measuring device 11 to transmit millimeter wave signals to the second measuring device 12 through the array antenna 112 of the first measuring device 11 at a first transmitting angle corresponding to the transmission environment for line-of-sight transmission. The second test module 104 searches the list, and controls the second measurement device 12 to receive the millimeter wave signal sent by the first measurement device 11 at a first incident angle corresponding to the transmission environment being the line of sight transmission through the array antenna 112 of the second measurement device 12. In this way, the downlink between the first measurement device 11 and the second measurement device 12 can be established quickly, thereby achieving the purpose of quick communication between the first measurement device 11 and the second measurement device 12.

And a second test request module 107, applied in the second measurement device 12, configured to send a second test request signal to the measurement controller 2, where the second test request signal includes location information of the second measurement device 12.

In this embodiment, the second test request module 107 sends the first test request signal containing the position information of the second measurement device 12 to the measurement controller 2 through the first antenna 113 in the second measurement device 12.

A fourth test response module 108, applied in the measurement controller 2, is configured to generate a seventh test instruction and an eighth test instruction according to the received second test request signal, send the seventh test instruction to the second measurement device 12, and send the eighth test instruction to the first measurement device 11.

In this embodiment, the fourth test response module 108 receives the second test request signal sent by the second measurement device 12 through the second antenna 21 of the measurement controller 2, generates a seventh test instruction and an eighth test instruction according to the received second test request signal, sends the seventh test instruction to the second measurement device 12 through the second antenna 21, sends the eighth test instruction to the first measurement device 11 through the second antenna 21, and stores the position information of the second measurement device 12 in the second test request signal.

The third test module 109 is applied in the second measurement device 12, and is configured to receive a seventh test instruction sent by the measurement controller 2 and control the omni-directional antenna 111 of the second measurement device 12 to send a millimeter wave signal to the first measurement device 11 according to the seventh test instruction.

In this embodiment, the second measuring device 12 controls the omnidirectional antenna 111 to transmit the millimeter wave signal to the first measuring device 11 after receiving the seventh test command transmitted by the measurement controller 2 through the first antenna 113.

The fourth testing module 120 is applied to the first measuring device 11, and is configured to receive an eighth testing instruction sent by the measuring controller 2, control the array antenna 112 of the first measuring device 11 to receive the millimeter wave signal sent by the second measuring device 12 according to the eighth testing instruction, determine a second incident angle of a beam of at least one millimeter wave signal according to a signal strength of the received millimeter wave signal, and send the position information of the first measuring device 11 and at least one second incident angle to the measuring controller 2.

In this embodiment, the fourth test module 120 controls the sector antennas in the four sectors of the array antenna 112 of the first measurement device 11 to scan and receive the millimeter wave signals sent by the second measurement device 12 at different incident angles according to the eighth test command sent by the measurement controller 2. The fourth test module 120 determines an incident angle corresponding to the received millimeter wave signal having a signal intensity exceeding a signal intensity threshold as a second incident angle and transmits the second incident angle and the position of the first measurement device 11 to the measurement controller 2. In this embodiment, when the fourth testing module 120 controls the sector antennas in the four sectors of the first measuring device 11 to scan within a preset cycle scan time and receive the millimeter wave signals sent by the second measuring device 12 at different incident angles, the four sectors receive the millimeter wave signals sent by the second measuring device 12 at different incident angles of beams through the sector antennas in 0 to 90 degrees, 90 to 180 degrees, 180 to 270 degrees, and 270 to 360 degrees, respectively.

In another embodiment, the fourth test module 120 controls the sector antennas in the three sectors of the first measurement device 11 to scan and receive the millimeter wave signals sent by the second measurement device 12 at different incident angles according to the eighth test instruction sent by the measurement controller 2. In this embodiment, when the fourth testing module 120 controls the sector antennas in the three sectors of the first measuring device 11 to scan within a preset cycle scan time and receive the millimeter wave signals sent by the second measuring device 12 at different incident angles, the three sectors receive the millimeter wave signals sent by the second measuring device 12 at different incident angles of beams through the sector antennas in 0 to 120 degrees, 120 to 240 degrees, and 240 to 360 degrees, respectively.

The fifth test response module 121 is applied in the measurement controller 2, and is configured to receive and store the first incident angle sent by the first measurement device 11 and the position information of the first measurement device 11, generate a ninth test instruction and a tenth test instruction, and send the ninth test instruction to the second measurement device 12 and the tenth test instruction to the first measurement device 11.

The third test module 109 receives a ninth test command sent by the measurement controller 2 through the first antenna 113 of the second measurement device 12, and controls the second measurement device 12 to send millimeter wave signals at different transmission angles through the array antenna 112 according to the ninth test command. In this embodiment, the third test module 109 controls the sector antennas in the four sectors of the second measurement device 12 to scan within the preset cyclic scan time according to the ninth test instruction sent by the measurement controller 2, and sends millimeter wave signals at different transmission angles. In this embodiment, when the third test module 109 controls the sector antennas in the four sectors of the second measurement device 12 to scan and transmit the millimeter wave signals at different transmission angles, the four sectors transmit the millimeter wave signals to the first measurement device 11 at different transmission angles through the array antenna 112 in 0 to 90 degrees, 90 to 180 degrees, 180 to 270 degrees, and 270 to 360 degrees, respectively.

The fourth test module 120 receives a tenth test instruction sent by the measurement controller 2 through the first antenna 113 of the first measurement device 11, and controls the first measurement device 11 to receive, through the array antenna 112, millimeter wave signals sent by the second measurement device 12 through the array antenna 112 of the second measurement device 12 at each second incident angle, respectively, according to the tenth test instruction.

In this embodiment, the fourth test module 120 determines whether the signal strength of the received millimeter wave signal exceeds a signal strength threshold, if the signal strength of the received millimeter wave signal exceeds the signal strength threshold, records a current second time period and a second signal strength, and sends the second time period and the second signal strength to the measurement controller 2. In this embodiment, the second signal strength is a signal strength corresponding to a millimeter wave signal whose signal strength exceeds a signal strength threshold when the first measuring device 11 receives the millimeter wave signal sent by the second measuring device 12 at least a fixed second incident angle; the first period is a time from when the array antenna 112 of the first measurement device 11 scans and receives the millimeter wave signal transmitted by the second measurement device 12 to when the signal strength of the received millimeter wave signal is the second signal strength.

The sixth test response module 122 is applied in the measurement controller 2, and is configured to receive the second time period and the second signal strength sent by the first measurement device 11, and send the second time period and the second signal strength to the second measurement device 12.

The third test module 109 determines a second emission angle corresponding to the second time period according to the second time period and the second signal strength sent by the measurement controller 2, and sends the second emission angle to the measurement controller 2. Specifically, the third test module 109 determines the second emission angle corresponding to the second period of time during a preset cyclic scan time of the scanning performed by the array antenna 112 of the second measurement device 12. The third test module 109 sends the second emission angle to the measurement controller 2 via the first antenna 113.

The sixth test response module 122 receives and stores the second emission angle sent by the second measurement device 12, generates an eleventh test instruction and a twelfth test instruction, and sends the eleventh test instruction to the second measurement device 12 and the twelfth test instruction to the first measurement device 11.

The third test module 109 controls the array antenna 112 of the second measurement device 12 to transmit a millimeter wave signal to the first measurement device 11 at the second emission angle according to the eleventh test instruction, and performs timing.

The fourth test module 120 controls the array antenna 112 of the first measurement device 11 to receive the millimeter wave signal sent by the second measurement device 12 at the second incident angle according to the twelfth test instruction, and sends a feedback signal to the second measurement device 12 through the array antenna 112 after receiving the millimeter wave signal sent by the second measurement device 12. The third test module 109 stops counting to obtain a second counted time when receiving the feedback signal, and sends the second counted time to the measurement controller 2. The sixth test response module 122 calculates a second path time according to the second timing time and the formula Tt '=t' -Tap '-Tbp', where T 'is the second timing time, tbp' is the time for the first measuring device 11 to process the millimeter wave signal received from the second measuring device 12, tap 'is the processing time for the second measuring device 12 to receive the feedback signal of the first measuring device 11, and Tt' is the second path time.

In this embodiment, the sixth test response module 122 calculates the third distance from the second path time according to the formula D ' =c×tt '/2, where C is the speed of light and D ' is the third distance. The sixth test response module 122 is further configured to calculate a fourth distance between the first measurement device 11 and the second measurement device 12 according to the position information of the first measurement device 11 and the position information of the second measurement device 12. The sixth test response module 122 calculates a difference between the third distance and the fourth distance and determines whether the calculated difference is greater than the preset distance range. When the difference is within the preset distance range, the sixth test response module 122 determines that the transmission environment between the first measurement device 11 and the second measurement device 12 is line-of-sight transmission. When the difference exceeds the preset distance range, the sixth test response module 122 determines that the transmission environment between the first measurement device 11 and the second measurement device 12 is a non-line-of-sight transmission. In this embodiment, the sixth test response module 122 establishes a correspondence between the position of the first measurement device 11, the position of the second measurement device 12, the second emission angle of the second measurement device 12, the second incident angle of the first measurement device 11, and the transmission environment between the first measurement device 11 and the second measurement device 12, and stores the correspondence in the list.

In this embodiment, the third test module 109 searches the list and controls the second measurement device 12 to transmit the millimeter wave signal to the first measurement device 11 through the array antenna 112 of the second measurement device 12 at a second emission angle corresponding to the transmission environment as the line of sight transmission. The fourth test module 120 searches the list and controls the first measurement device 11 to receive the millimeter wave signal sent by the second measurement device 12 through the array antenna 112 of the first measurement device 11 at a second incident angle corresponding to the transmission environment being the line of sight transmission. In this way, the uplink between the second measurement device 12 and the first measurement device 11 can be established quickly, thereby achieving the purpose of quick communication between the first measurement device 11 and the second measurement device 12.

The updating module 123 is applied to the first measuring device 11 or the second measuring device 12, and is configured to send a new test request signal to the measurement controller 2 when detecting that the first measuring device 11 or the second measuring device 12 moves to a new position, where the test request signal includes position information of the first measuring device 11 or the second measuring device 12 after moving. In this embodiment, when the first measuring device 11 or the second measuring device 12 moves in a geographical area, the geographical area may be divided into a plurality of sub-areas with the same size, wherein the size of the sub-areas is 20m×20m; the first measuring device 11 or the second measuring device 12 is then moved from one sub-area to the other sub-area of the geographical area.

Referring to fig. 8, a flowchart of a method for determining a communication path of a millimeter wave signal according to an embodiment of the invention is shown. The order of the steps in the flowcharts may be changed, and some steps may be omitted or combined according to different needs. The method comprises the steps of:

in step S701, the first measurement device 11 sends a first test request signal to the measurement controller 2, where the first test request signal includes location information of the first measurement device 11.

In the present embodiment, the first measuring device 11 transmits the first test request signal containing the position information of the first measuring device 11 to the measurement controller 2 through the first antenna 113 in the first measuring device 11.

In step S702, the measurement controller 2 generates a first test command and a second test command according to the received first test request signal, sends the first test command to the first measurement device 11, and sends the second test command to the second measurement device 12.

In this embodiment, the measurement controller 2 receives the first test request signal sent by the first measurement device 11 through the second antenna 21, generates a first test instruction and a second test instruction according to the received first test request signal, sends the first test instruction to the first measurement device 11 through the second antenna 21, sends the second test instruction to the second measurement device 12 through the second antenna 21, and stores the position information of the first measurement device 11 in the first test request signal.

In step S703, the first measuring device 11 receives the first test command sent by the measurement controller 2 and controls the omni-directional antenna 111 of the first measuring device 11 to send a millimeter wave signal to the second measuring device 12 according to the first test command.

In step S704, the second measuring device 12 receives the second test instruction sent by the measuring controller 2, and controls the array antenna 112 of the second measuring device 12 to receive the millimeter wave signal sent by the first measuring device 11 through the omni-directional antenna 111 of the first measuring device 11 according to the second test instruction, and determines the first incident angle of the beam of at least one millimeter wave signal according to the signal strength of the received millimeter wave signal, and sends the position information of the second measuring device 12 and the at least one first incident angle to the measuring controller 2.

In this embodiment, the array antenna 112 has four sectors, each having at least one sector antenna. The second measuring device 12 controls sector antennas in the four sectors of the array antenna 112 of the second measuring device 12 to scan according to the second test instruction sent by the measuring controller 2 and receives millimeter wave signals sent by the first measuring device 11 at different incident angles. The second measuring device 12 determines an incident angle corresponding to the received millimeter wave signal when the signal intensity exceeds a signal intensity threshold value as a first incident angle and transmits the first incident angle and the position of the second measuring device 12 to the measurement controller 2. In this embodiment, when the second measuring device 12 controls the sector antennas in the four sectors of the second measuring device 12 to scan within a preset cycle scan time and receive the millimeter wave signals sent by the first measuring device 11 at different incident angles, the four sectors receive the millimeter wave signals sent by the first measuring device 11 at different incident angles of beams through the sector antennas in 0 to 90 degrees, 90 to 180 degrees, 180 to 270 degrees, and 270 to 360 degrees, respectively. In this embodiment, the sector antenna is a 1×16 antenna structure or a 1×8 antenna structure.

In another embodiment, the array antenna 112 has three sectors, each sector having at least one sector antenna. The second measuring device 12 controls sector antennas in the three sectors of the second measuring device 12 to scan according to the second test instruction sent by the measuring controller 2 and receives millimeter wave signals sent by the first measuring device 11 at different incident angles. In this embodiment, when the second measuring device 12 controls the sector antennas in the three sectors of the second measuring device 12 to scan within a preset cycle scan time and receive the millimeter wave signals sent by the first measuring device 11 at different incident angles, the three sectors receive the millimeter wave signals sent by the first measuring device 11 at different incident angles of beams through the sector antennas in 0 to 120 degrees, 120 to 240 degrees, and 240 to 360 degrees, respectively.

In step S705, the measurement controller 2 receives and stores the first incident angle transmitted by the second measurement device 12 and the position information of the second measurement device 12, generates a third test instruction and a fourth test instruction, and transmits the third test instruction to the first measurement device 11 and the fourth test instruction to the second measurement device 12.

In step S706, the first measuring device 11 receives the third test instruction sent by the measurement controller 2 through the first antenna 113 of the first measuring device 11, and controls the first measuring device 11 to send millimeter wave signals at different transmission angles through the array antenna 112 according to the third test instruction. In this embodiment, the first measuring device 11 controls the sector antennas in the four sectors of the first measuring device 11 to scan in the preset cyclic scan time according to the third test instruction sent by the measurement controller 2, and sends millimeter wave signals at different emission angles. In this embodiment, when the first measuring device 11 controls the sector antennas in the four sectors of the first measuring device 112 to scan and transmit the millimeter wave signals at different transmission angles, the four sectors transmit the millimeter wave signals to the second measuring device 12 at different transmission angles through the array antenna 112 in 0 to 90 degrees, 90 to 180 degrees, 180 to 270 degrees, and 270 to 360 degrees, respectively.

In step S707, the second measuring device 12 receives, through the first antenna 113 of the second measuring device 12, the fourth test instruction sent by the measurement controller 2, and controls, according to the fourth test instruction, the second measuring device 12 to receive, through the array antenna 112, the millimeter wave signal sent by the first measuring device 11 through the array antenna 112 of the first measuring device 11 at each first incident angle, respectively.

In step S708, the second measurement device 12 determines whether the signal strength of the received millimeter wave signal exceeds a signal strength threshold, if so, records the current first time period and the first signal strength, and sends the first time period and the first signal strength to the measurement controller 2.

In step S709, the measurement controller 2 receives the first time period and the first signal strength sent by the second measurement device 12, and sends the first time period and the first signal strength to the first measurement device 11.

In step S710, the first measuring device 11 receives the first time period and the first signal strength sent by the measurement controller 2, determines a first emission angle corresponding to the first time period according to the first time period and the first signal strength, and sends the first emission angle to the measurement controller 2. The first signal strength is a time from when the second measuring device 12 receives a signal that the signal strength sent by the measuring device exceeds a signal strength threshold value at least one fixed first incident angle, and the first time period is a time from when the first measuring device 11 sends millimeter wave signals at different transmitting angles to when the second measuring device 12 receives the first signal strength at least one fixed first incident angle. In this embodiment, the first measuring device 11 determines the first emission angle corresponding to the first period in a preset cyclic scan time for scanning by the array antenna 112 of the first measuring device 11. The first measuring device 11 transmits the first emission angle to the measurement controller 2 via the first antenna 113.

In step S711, the measurement controller 2 receives and stores the first emission angle sent by the first measurement device 11, generates a fifth test instruction and a sixth test instruction, and sends the fifth test instruction to the first measurement device 11 and the sixth test instruction to the second measurement device 12.

In step S712, the first measuring device 11 controls the array antenna 112 of the first measuring device 11 to transmit the millimeter wave signal to the second measuring device 12 at the first transmitting angle according to the fifth test command, and performs timing.

In step S713, the second measuring device 12 controls the array antenna 112 of the second measuring device 12 to receive the millimeter wave signal sent by the first measuring device 11 at the first incident angle according to the sixth test command, and sends a feedback signal to the first measuring device 11 through the array antenna 112 after receiving the millimeter wave signal sent by the first measuring device 11.

In step S714, the first measuring device 11 stops counting to obtain a first counted time when receiving the feedback signal, and sends the first counted time to the measurement controller 2.

In step S715, the measurement controller 2 calculates the first path time according to the formula tt=t-Tap-Tbp, where T is the first timing time, tbp is the time for the second measurement device 12 to process the millimeter wave signal received from the first measurement device 11, tap is the processing time for the first measurement device 11 to receive the feedback signal from the second measurement device 12, and Tt is the first path time. In this embodiment, since the time of the Tap and the Tbp is not changed in different transmission environments, the total time of the Tap and the Tbp can be measured in a known transmission environment.

In step S716, the measurement controller 2 calculates a first distance from the first path time according to the formula d=c×tt/2, where C is a light speed, D is the first distance, and calculates a second distance between the first measurement device 11 and the second measurement device 12 according to the position information of the first measurement device 11 and the position information of the second measurement device 12.

In step S717, the measurement controller 2 calculates a difference between the second distance and the first distance, and determines whether the calculated difference is greater than a preset distance range, when the difference is within the preset distance range, the measurement controller 2 determines that the transmission environment between the first measurement device 11 and the second measurement device 12 is line-of-sight transmission, and when the difference exceeds the preset distance range, determines that the transmission environment between the first measurement device 11 and the second measurement device 12 is non-line-of-sight transmission.

In step S718, the measurement controller 2 establishes a correspondence between the position of the first measurement device 11, the position of the second measurement device 12, the first incident angle of the second measurement device 12, the first emission angle of the first measurement device 11, and the transmission environment between the first measurement device 11 and the second measurement device 12, and stores the correspondence in a list.

In step S719, the first measuring device 111 searches the list, and transmits the millimeter wave signal to the second measuring device 12 at the first transmitting angle corresponding to the transmission environment as the line of sight transmission through the array antenna 112 of the first measuring device 11.

In step S720, the second measuring device 12 searches the list, and receives, through the array antenna 112 of the second measuring device 12, the millimeter wave signal transmitted by the first measuring device 11 at the first incident angle corresponding to the transmission environment being the line of sight transmission.

In this way, the downlink between the first measurement device 11 and the second measurement device 12 can be established quickly, thereby achieving the purpose of quick communication between the first measurement device 11 and the second measurement device 12.

In this embodiment, the method further includes: the second measurement device 12 sends a second test request signal to the measurement controller 2, where the second test request signal includes location information of the second measurement device 12.

In this embodiment, the method further includes: the measurement controller 2 generates a seventh test instruction and an eighth test instruction according to the received second test request signal, sends the seventh test instruction to the second measurement device 12, and sends the eighth test instruction to the first measurement device 11.

In this embodiment, the method further includes: the second measuring device 12 receives the seventh test command sent by the measuring controller 2 and controls the omnidirectional antenna 111 of the second measuring device 12 to send a millimeter wave signal to the first measuring device 11 according to the seventh test command.

In this embodiment, the method further includes: the first measuring device 11 receives the eighth test instruction sent by the measuring controller 2, controls the array antenna 112 of the first measuring device 11 to receive the millimeter wave signal sent by the second measuring device 12 according to the eighth test instruction, determines a second incident angle of a beam of at least one millimeter wave signal according to the signal strength of the received millimeter wave signal, and sends the position information of the first measuring device 11 and the at least one second incident angle to the measuring controller 2.

In this embodiment, the method further includes: the measurement controller 2 receives and stores the first incident angle transmitted by the first measurement device 11 and the position information of the first measurement device 11, generates a ninth test instruction and a tenth test instruction, and transmits the ninth test instruction to the second measurement device 12 and the tenth test instruction to the first measurement device 11.

In this embodiment, the method further includes: the second measuring device 12 receives the ninth test command sent by the measurement controller 2 through the first antenna 113 of the second measuring device 12 and controls the second measuring device 12 to send millimeter wave signals at different transmitting angles through the array antenna 112 according to the ninth test command. In this embodiment, the second measurement device 12 controls the sector antennas in the four sectors of the second measurement device 12 to scan within the preset cyclic scan time according to the ninth test instruction sent by the measurement controller 2, and sends millimeter wave signals at different transmission angles.

In this embodiment, the method further includes: the first measuring device 11 receives a tenth test instruction sent by the measurement controller 2 through the first antenna 113 of the first measuring device 11, and controls the first measuring device 11 to receive millimeter wave signals sent by the second measuring device 12 through the array antenna 112 of the second measuring device 12 through the array antenna 112 at each second incident angle respectively according to the tenth test instruction.

In this embodiment, the method further includes: the first measuring device 11 determines whether the signal strength of the received millimeter wave signal exceeds a signal strength threshold, if the signal strength of the received millimeter wave signal exceeds the signal strength threshold, records a current second time period and a second signal strength, and sends the second time period and the second signal strength to the measurement controller 2.

In this embodiment, the method further includes: the measurement controller 2 receives the second time period and the second signal strength transmitted from the first measurement device 11, and transmits the second time period and the second signal strength to the second measurement device 12.

In this embodiment, the method further includes: the second measuring device 12 determines a second emission angle corresponding to a second time period according to the second time period and the second signal intensity sent by the measurement controller 2, and sends the second emission angle to the measurement controller 2. Specifically, the second measuring device 12 determines the second emission angle corresponding to the second period of time during a preset cyclic scan time of the scanning performed by the array antenna 112 of the second measuring device 12. The second measuring device 12 sends the second emission angle to the measurement controller 2 via the first antenna 113.

In this embodiment, the method further includes: the measurement controller 2 receives and stores the second emission angle transmitted from the second measurement device 12, generates an eleventh test instruction and a twelfth test instruction, and transmits the eleventh test instruction to the second measurement device 12 and the twelfth test instruction to the first measurement device 11.

In this embodiment, the method further includes: the second measuring device 12 controls the array antenna 112 of the second measuring device 12 to transmit a millimeter wave signal to the first measuring device 11 at the second emission angle according to the eleventh test instruction, and performs timing.

In this embodiment, the method further includes: the first measuring device 11 controls the array antenna 112 of the first measuring device 11 to receive the millimeter wave signal sent by the second measuring device 12 at the second incident angle according to the twelfth test instruction, and sends a feedback signal to the second measuring device 12 through the array antenna 112 after receiving the millimeter wave signal sent by the second measuring device 12.

In this embodiment, the method further includes: the second measuring device 12 stops counting to obtain a second counted time when receiving the feedback signal, and sends the second counted time to the measurement controller 2.

In this embodiment, the method further includes: the measurement controller 2 calculates a second path time according to the second timing time and the formula Tt '=t' -Tap '-Tbp', where T 'is the second timing time, tbp' is the time for the first measurement device 11 to process the millimeter wave signal received from the second measurement device 12, tap 'is the processing time for the second measurement device 12 to receive the feedback signal of the first measurement device 11, and Tt' is the second path time.

In this embodiment, the method further includes: the measurement controller 2 calculates a third distance from the second path time according to the formula D ' =c×tt '/2, where C is the speed of light and D ' is the third distance; calculating a fourth distance between the first measuring device 11 and the second measuring device 12 according to the position information of the first measuring device 11 and the position information of the second measuring device 12; and calculating a difference value between the third distance and the fourth distance, and judging whether the calculated difference value is larger than the preset distance range.

When the difference is within the preset distance range, the measurement controller 2 determines that the transmission environment between the first measurement device 11 and the second measurement device 12 is line-of-sight transmission. When the difference exceeds the preset distance range, the measurement controller 2 determines that the transmission environment between the first measurement device 11 and the second measurement device 12 is a non-line-of-sight transmission.

In the present embodiment, the measurement controller 2 associates and stores the position of the first measurement device 11, the position of the second measurement device 12, the second emission angle of the second measurement device 12, the second incident angle of the first measurement device 11, and the transmission environment between the first measurement device 11 and the second measurement device 12 in the list.

In this embodiment, the method further includes: the second measuring device 12 searches the list and transmits millimeter wave signals to the first measuring device 11 through the array antenna 112 of the second measuring device 12 at a second transmitting angle corresponding to the transmission environment as a line of sight transmission; the first measuring device 11 searches the list, and receives the millimeter wave signal sent by the first measuring device 11 through the array antenna 112 of the first measuring device 11 at a second incident angle corresponding to the transmission environment as the line of sight transmission.

In this way, the uplink between the second measurement device 12 and the first measurement device 11 can be established quickly, thereby achieving the purpose of quick communication between the first measurement device 11 and the second measurement device 12.

In this embodiment, the method further includes: when the first measuring device 11 detects that the first measuring device 11 moves to a new position, the first measuring device 11 sends a new test request signal to the measurement controller 2, wherein the test request signal contains position information of the first measuring device 11 after moving. In this embodiment, when the first measuring device 11 moves in a geographical area, the geographical area may be divided into a plurality of sub-areas with the same size, where the size of the sub-areas is 20m×20m; the first measuring device 11 is then moved from one sub-area to another sub-area of the geographical area.

The above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the above preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present invention.

Claims

1. The utility model provides a measuring device, measuring device and measurement controller and second measuring device communication connection, its characterized in that, measuring device includes omnidirectional antenna, array antenna, first antenna and treater, the treater respectively with omnidirectional antenna array antenna, first antenna is connected, the treater is used for:

receiving a first test instruction sent by the measurement controller through the first antenna, and controlling an omnidirectional antenna of the measurement device to send millimeter wave signals to the second measurement device according to the first test instruction; the array antenna of the second measuring device receives millimeter wave signals sent by the measuring device through the omnidirectional antenna of the measuring device, and determines a first incidence angle of a wave beam of at least one millimeter wave signal according to the signal intensity of the received millimeter wave signals;

the method comprises the steps of receiving a first time period and first signal intensity sent by a measurement controller, determining a first sending angle corresponding to the first time period according to the first time period and the first signal intensity, and sending the first sending angle to the measurement controller, wherein the first signal intensity is the signal intensity corresponding to millimeter wave signals with signal intensity exceeding a signal intensity threshold value when the second measurement device receives the millimeter wave signals sent by the measurement device through an array antenna at least at a fixed first incidence angle, and the first time period is the time from the scanning of the millimeter wave signals sent by the measurement device to the reception of the millimeter wave signals with the signal intensity being the first signal intensity;

Stopping timing when the measuring device receives the feedback signal of the second measuring device to obtain a first timing time, and sending the first timing time to the measuring controller; a kind of electronic device with high-pressure air-conditioning system

Searching a list, transmitting millimeter wave signals to a second measuring device through an array antenna of the measuring device at a first transmitting angle corresponding to the transmission environment as a line of sight, wherein the list stores the position of the measuring device, the position of the second measuring device, a first incident angle of the second measuring device, the first transmitting angle of the measuring device and the transmission environment between the measuring device and the second measuring device to establish a corresponding relation.

2. The measurement device of claim 1, wherein the processor is further configured to:

and receiving a second test instruction sent by the measurement controller, controlling an array antenna of the measurement device to receive millimeter wave signals sent by the second measurement device through an omnidirectional antenna of the second measurement device according to the second test instruction, determining a second incidence angle of a wave beam of at least one millimeter wave signal according to the signal intensity of the received millimeter wave signals, and sending the position information of the measurement device and the at least one second incidence angle to the measurement controller.

3. The measurement device of claim 2, wherein the processor is further configured to:

and controlling sector antennas in four sectors of an array antenna of the measuring device to scan in a preset cyclic scanning time according to the second test instruction sent by the measuring controller, receiving millimeter wave signals sent by the second measuring device at different incidence angles, determining the incidence angle corresponding to the received millimeter wave signals when the signal intensity of the millimeter wave signals exceeds a signal intensity threshold value as a second incidence angle, and sending the second incidence angle and the position of the measuring device to the measuring controller.

4. A measuring device according to claim 3, wherein the processor is further configured to:

receiving a fourth test instruction sent by the measurement controller through a first antenna of the measurement device, and controlling the measurement device to respectively receive millimeter wave signals sent by the second measurement device through the array antenna of the second measurement device at each second incident angle according to the fourth test instruction; a kind of electronic device with high-pressure air-conditioning system

Judging whether the signal intensity of the received millimeter wave signal exceeds the signal intensity threshold value, if so, recording the current second time period and the current second signal intensity, and sending the second time period and the current second signal intensity to the measurement controller.

5. The measurement device of claim 4, wherein the processor is further configured to:

and receiving a sixth test instruction sent by the measurement controller, controlling an array antenna of the measurement device to receive the millimeter wave signal sent by the second measurement device at the second incident angle according to the sixth test instruction, and sending a feedback signal to the second measurement device through the array antenna of the measurement device after receiving the millimeter wave signal sent by the second measurement device.

6. The measurement device of claim 5, wherein the processor is further configured to:

and searching the list, and receiving millimeter wave signals sent by the second measuring device through the array antenna of the measuring device at a second incident angle corresponding to the transmission environment as a line of sight transmission, wherein the list also stores the position of the measuring device, the position of the second measuring device, the second emission angle of the second measuring device, the second incident angle of the measuring device and the transmission environment between the measuring device and the second measuring device to establish a corresponding relation.

7. The utility model provides a measurement controller, respectively with first measuring device and second measuring device communication connection, measurement controller includes second antenna and processing unit, the second antenna with processing unit connects, its characterized in that, processing unit is used for:

Receiving a first test request signal which is sent by the first measuring device and contains the position of the first measuring device through the second antenna, generating a first test instruction and a second test instruction according to the received first test request signal, sending the first test instruction to the first measuring device, sending the second test instruction to the second measuring device, and storing the position of the first measuring device; the second measuring device receives a second test instruction sent by the measuring controller, controls an array antenna of the measuring device to receive millimeter wave signals sent by the first measuring device through an omni-directional antenna of the first measuring device according to the second test instruction, and determines a first incidence angle of a wave beam of at least one millimeter wave signal according to the signal intensity of the received millimeter wave signals;

Receiving a first time period and a first signal intensity sent by the second measuring device, and sending the first time period and the first signal intensity to the first measuring device, wherein the first signal intensity is the signal intensity corresponding to a millimeter wave signal with the signal intensity exceeding a signal intensity threshold when the second measuring device receives the millimeter wave signal sent by the first measuring device through an array antenna at different transmitting angles at least one fixed first incidence angle, and the first time period is the time from the time when the second measuring device scans and receives the millimeter wave signal sent by the first measuring device to the time when the signal intensity of the millimeter wave signal is the first signal intensity;

transmitting the first time period and a first signal strength to the first measuring device; the first measuring device receives a first time period and first signal intensity sent by the measuring controller, and determines a first emission angle corresponding to the first time period according to the first time period and the first signal intensity;

the first path time is calculated according to the formula d=c

Tt/2 calculates a first distance, wherein C is the speed of light and D is the first distance;

8. The measurement controller of claim 7, wherein the processing unit is further to:

generating a seventh test instruction and an eighth test instruction according to a second test request signal sent by the second measuring device, sending the seventh test instruction to the second measuring device, and sending the eighth test instruction to the first measuring device;

receiving and storing at least one second incident angle sent by the first measuring device and position information of the first measuring device, generating a ninth test instruction and a tenth test instruction, and sending the ninth test instruction to the second measuring device and the tenth test instruction to the first measuring device; the first measuring device controls an array antenna of the first measuring device to receive millimeter wave signals sent by the second measuring device according to the eighth test instruction, and determines the at least one second incident angle according to the received signal strength of the millimeter wave signals sent by the second measuring device;

Receiving a second time period and second signal intensity sent by the first measuring device, and sending the second time period and the second signal intensity to the second measuring device, wherein the first measuring device receives millimeter wave signals sent by the second measuring device through the array antenna of the second measuring device at each second incident angle through the array antenna of the first measuring device, and records the second time period and the second signal intensity when the signal intensity of the millimeter wave signals sent by the second measuring device through the array antenna of the second measuring device exceeds a signal intensity threshold;

receiving and storing a second emission angle sent by the second measuring device, generating an eleventh test instruction and a twelfth test instruction, and sending the eleventh test instruction to the second measuring device and the twelfth test instruction to the first measuring device; the second measuring device determines a second emission angle corresponding to the second time period according to the second time period and the second signal intensity sent by the measuring controller;

receiving a second timing time sent by the second measuring device, and calculating a second path time according to the second timing time according to a formula Tt '=t' -Tap '-Tbp', wherein T 'is the second timing time, tbp' is the time for the first measuring device to process the millimeter wave signal received from the second measuring device, tap 'is the processing time for the second measuring device to receive the feedback signal of the first measuring device, and Tt' is the second path time;

The second path time is calculated according to the formula D' =c

Tt '/2 calculates a third distance, wherein C is the speed of light and D' is the third distance;

calculating a fourth distance between the first measuring device and the second measuring device according to the position information of the first measuring device and the position information of the second measuring device, and calculating a difference value between the third distance and the fourth distance;

determining that the transmission environment between the first measurement device and the second measurement device is line-of-sight transmission when the difference between the third distance and the fourth distance is within the preset distance range, and determining that the transmission environment between the first measurement device and the second measurement device is non-line-of-sight transmission when the difference between the third distance and the fourth distance exceeds the preset distance range; a kind of electronic device with high-pressure air-conditioning system

And establishing a corresponding relation among the position of the first measuring device, the position of the second measuring device, the second emission angle of the second measuring device, the second incident angle of the first measuring device and the transmission environment between the first measuring device and the second measuring device and storing the corresponding relation in the list.

9. A method for determining a communication path of a millimeter wave signal, the method being applied to a first measuring device, a second measuring device and a measuring controller, the measuring controller being communicatively connected to the first measuring device and the second measuring device, respectively, the method comprising:

The measurement controller calculates the first path time according to the formula d=c

Tt/2 calculates a first distance, wherein C is the speed of light, D is the first distance, and a second distance between the first measuring device and the second measuring device is calculated according to the position information of the first measuring device and the position information of the second measuring device;

10. The communication path determining method of the millimeter wave signal according to claim 9, wherein the method further comprises:

the measurement controller generates a seventh test instruction and an eighth test instruction according to a second test request signal which is sent by the second measurement device and contains the position of the second measurement device, sends the seventh test instruction to the second measurement device, and sends the eighth test instruction to the first measurement device;

the second measuring device controls an omnidirectional antenna of the second measuring device to send millimeter wave signals to the first measuring device according to the seventh test instruction;

the first measuring device controls an array antenna of the first measuring device to receive millimeter wave signals sent by the second measuring device according to the eighth test instruction, determines a second incidence angle of a beam of at least one millimeter wave signal according to the signal intensity of the received millimeter wave signals, and sends position information of the first measuring device and at least one second incidence angle to the measuring controller;

The measurement controller receives and stores the second incident angle sent by the first measurement device and the position information of the first measurement device, generates a ninth test instruction and a tenth test instruction, and sends the ninth test instruction to the second measurement device and the tenth test instruction to the first measurement device;

the second measuring device controls the second measuring device to respectively send millimeter wave signals at different transmitting angles through an array antenna of the second measuring device according to the ninth test instruction;

the first measuring device controls the first measuring device to receive millimeter wave signals sent by the second measuring device through the array antenna of the first measuring device at each second incident angle according to the tenth test instruction;

the first measuring device judges whether the signal intensity of the received millimeter wave signal exceeds a signal intensity threshold value, if so, records a current second time period and a second signal intensity, and sends the second time period and the second signal intensity to the measuring controller;

The measurement controller receives a second time period and a second signal intensity sent by the first measurement device and sends the second time period and the second signal intensity to the second measurement device;

the second measuring device determines a second emission angle corresponding to a second time period according to the second time period and the second signal intensity sent by the measuring controller, and sends the second emission angle to the measuring controller;

the measurement controller receives and stores a second emission angle sent by the second measurement device, generates an eleventh test instruction and a twelfth test instruction, and sends the eleventh test instruction to the second measurement device and the twelfth test instruction to the first measurement device;

the second measuring device controls an array antenna of the second measuring device to send millimeter wave signals to the first measuring device at the second emission angle according to the eleventh test instruction, and the second measuring device is timed;

the first measuring device controls an array antenna of the first measuring device to receive the millimeter wave signal sent by the second measuring device at the second incident angle according to the twelfth test instruction, and sends a second feedback signal to the second measuring device through the array antenna after receiving the millimeter wave signal sent by the second measuring device;

Stopping timing when the second measuring device receives the second feedback signal to obtain second timing time, and sending the second timing time to the measuring controller;

the measurement controller calculates a second path time according to the second timing time and a formula Tt '=t' -Tap '-Tbp', wherein T 'is the second timing time, tbp' is the time of the first measurement device processing the millimeter wave signal received from the second measurement device, tap 'is the processing time of the second measurement device receiving the second feedback signal of the first measurement device, and Tt' is the second path time;

the measurement controller calculates the second path time according to the formula D' =c

Tt '/2 calculates a third distance, wherein C is the speed of light and D' is the third distance; calculating a fourth distance between the first measuring device and the second measuring device according to the position of the first measuring device and the position of the second measuring device; calculating a difference between the third distance and the fourth distance, and determining whether the calculated difference is greater than the fourth distancePresetting a distance range;

the measurement controller determines that a transmission environment between the first measurement device and the second measurement device is line-of-sight transmission when a difference between the third distance and the fourth distance is within the preset distance range, and determines that a transmission environment between the first measurement device and the second measurement device is non-line-of-sight transmission when the difference between the third distance and the fourth distance exceeds the preset distance range;

The measurement controller establishes a correspondence between the position of the first measurement device, the position of the second measurement device, the second emission angle of the second measurement device, the second incident angle of the first measurement device, and the transmission environment between the first measurement device and the second measurement device and stores the correspondence in the list;

the second measuring device searches the list and transmits millimeter wave signals to the first measuring device through an array antenna of the second measuring device at a second transmitting angle corresponding to the transmission environment as a line of sight transmission; a kind of electronic device with high-pressure air-conditioning system

The first measuring device searches the list, and receives millimeter wave signals sent by the first measuring device through an array antenna of the first measuring device at a second incident angle corresponding to transmission environment as line of sight transmission.

11. The communication path determining method of the millimeter wave signal according to claim 9, wherein the method further comprises:

the first measuring device sends a new test request signal to the measurement controller when detecting that the first measuring device moves to a new position.